AU610196B2 - Improved pipe liner process and apparatus - Google Patents

Improved pipe liner process and apparatus Download PDF

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Publication number
AU610196B2
AU610196B2 AU18938/88A AU1893888A AU610196B2 AU 610196 B2 AU610196 B2 AU 610196B2 AU 18938/88 A AU18938/88 A AU 18938/88A AU 1893888 A AU1893888 A AU 1893888A AU 610196 B2 AU610196 B2 AU 610196B2
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Australia
Prior art keywords
section
liner
pipe
tubular cross
cross
Prior art date
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AU18938/88A
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AU1893888A (en
Inventor
Luc R. Fourgaut
Patrick R. Ledoux
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Pipe Liners Inc
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Pipe Liners Inc
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Priority claimed from US07/077,883 external-priority patent/US4863365A/en
Priority claimed from US07114949 external-priority patent/US4985196B1/en
Priority claimed from US07188468 external-priority patent/US4986951B1/en
Application filed by Pipe Liners Inc filed Critical Pipe Liners Inc
Publication of AU1893888A publication Critical patent/AU1893888A/en
Application granted granted Critical
Publication of AU610196B2 publication Critical patent/AU610196B2/en
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Classifications

    • BPERFORMING OPERATIONS; TRANSPORTING
    • B29WORKING OF PLASTICS; WORKING OF SUBSTANCES IN A PLASTIC STATE IN GENERAL
    • B29CSHAPING OR JOINING OF PLASTICS; SHAPING OF MATERIAL IN A PLASTIC STATE, NOT OTHERWISE PROVIDED FOR; AFTER-TREATMENT OF THE SHAPED PRODUCTS, e.g. REPAIRING
    • B29C53/00Shaping by bending, folding, twisting, straightening or flattening; Apparatus therefor
    • B29C53/02Bending or folding
    • B29C53/08Bending or folding of tubes or other profiled members
    • B29C53/086Bending or folding of tubes or other profiled members bending radially, i.e. deformig the cross-section of the tube
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B29WORKING OF PLASTICS; WORKING OF SUBSTANCES IN A PLASTIC STATE IN GENERAL
    • B29CSHAPING OR JOINING OF PLASTICS; SHAPING OF MATERIAL IN A PLASTIC STATE, NOT OTHERWISE PROVIDED FOR; AFTER-TREATMENT OF THE SHAPED PRODUCTS, e.g. REPAIRING
    • B29C63/00Lining or sheathing, i.e. applying preformed layers or sheathings of plastics; Apparatus therefor
    • B29C63/26Lining or sheathing of internal surfaces
    • B29C63/34Lining or sheathing of internal surfaces using tubular layers or sheathings
    • B29C63/343Lining or sheathing of internal surfaces using tubular layers or sheathings the tubular sheathing having a deformed non-circular cross-section prior to introduction
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B29WORKING OF PLASTICS; WORKING OF SUBSTANCES IN A PLASTIC STATE IN GENERAL
    • B29CSHAPING OR JOINING OF PLASTICS; SHAPING OF MATERIAL IN A PLASTIC STATE, NOT OTHERWISE PROVIDED FOR; AFTER-TREATMENT OF THE SHAPED PRODUCTS, e.g. REPAIRING
    • B29C67/00Shaping techniques not covered by groups B29C39/00 - B29C65/00, B29C70/00 or B29C73/00
    • B29C67/0014Shaping techniques not covered by groups B29C39/00 - B29C65/00, B29C70/00 or B29C73/00 for shaping tubes or blown tubular films
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F16ENGINEERING ELEMENTS AND UNITS; GENERAL MEASURES FOR PRODUCING AND MAINTAINING EFFECTIVE FUNCTIONING OF MACHINES OR INSTALLATIONS; THERMAL INSULATION IN GENERAL
    • F16LPIPES; JOINTS OR FITTINGS FOR PIPES; SUPPORTS FOR PIPES, CABLES OR PROTECTIVE TUBING; MEANS FOR THERMAL INSULATION IN GENERAL
    • F16L57/00Protection of pipes or objects of similar shape against external or internal damage or wear

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  • Engineering & Computer Science (AREA)
  • Mechanical Engineering (AREA)
  • General Engineering & Computer Science (AREA)
  • Manufacturing & Machinery (AREA)
  • Lining Or Joining Of Plastics Or The Like (AREA)
  • Extrusion Moulding Of Plastics Or The Like (AREA)
  • Shaping Of Tube Ends By Bending Or Straightening (AREA)
  • Protection Of Pipes Against Damage, Friction, And Corrosion (AREA)

Description

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61019 COMMONWEALTH OF AUSTRALIA PATENTS ACT 1952 Form COMPLETE SPECIFICATION
(ORIGINAL)
FOR OFFICE USE Class Int. Class Application Number: Lodged: Complete Specification-Lodged: .4 Accepted Published: a..riori ty: '1'hiS docume11nt C-"'U4,ihs the amendments made uinc r Section 49 and is correct for Iprinting li 4 $elated Art: TO BE COMPLETED By APPLICANT Name of Applicant: PIPE LINERS, INC.
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*44444 4 0 4 Address of Applicant: 3421 N. Causeway Blvd., Netairie, Louisiana 70002. U.S.A.
Actual Inventor: Patrick R LEDOUX and Luc R FOURGAUT Address for Service: S/ANDERCOCK, SMfITH BEADLE 207 Riversda].e Road, Box .410) Hawthorn, Victoria, 3122 Complete Specification for the invention entitled: Improved pipe liner process and apparatus The following statement is a full description of this invention, including the best method of performing it known to me: 4I la This invention relates to the use of thermoplastic liners within pipe lines, either Iinitially or as a repair, for protecting the internal walls from deterioration. For deteriorated or damaged piping, the liner restores the fluid Sr transporting capability of the piping and prevents further interior deterioration. One such liner for protecting the interior of pipe is taught by French Patent No. 81 07346 dated April 13, 1981.
,0 It is a general object of this invention to provide methods and apparatus for the manufacture of a deformed tube product useful as pipe liners of the type disclosed in the Laurent patent as well as apparatus and methods for inserting the pipe liner within the pipe.
:SUMMARY OF THE INVENTION The present method of manufacturing a deformed tube product involves a first step of extruding a pipe liner having a tubular cross-section, and a second step of deforming the extruded tube into a reduced cross-section for insertion into a pipe as a liner therefor. A feature of this method of manufacturing a tube product is the use of ht i 2 thermoplastic material and its temperature control at the successive stages of formation, during extrusion into its initial and subsequent form, during its deformation, and during its return to ambient usable condition upon installation into the pipe. It is an object of this invention to provide a method and apparatus for the manufacture of pipe liners in continuous deformed lengths as well as methods and apparatus for inserting the liners into pipe for subsequently returning the liners in the pipe to their original unstressed extruded cross-section. In tri practice, the liner configuration has an outside diameter equal to or slightly greater than the inside diameter of the pipe to be protected, whereby the liner is either unstressed or under slight circumferential compression; either of which conditions is readily accommodated by the plastic liner which relies upon the surrounding pipe for its structural support.
It is another object of this invention to deform 'an initially extruded tubular cross-section without adverse effect on its structural integrity, and in such a manner that its initially extruded tubular cross-section can be restored. To this end, controlled heat is applied to establish a softened condition of the thermoplastic material after its extrusion, while simultaneously applying deforming tools thereto in order to reduce its cross-sectional configuration. When the desired reduction is t r7z 3 storage, transport and subsequent installation.
While a U-shaped reduced tubular configuration is particularly shown and described, it is to be understood that a V-shape or other cross-sectional configurations may be used, whether they be H-shaped or X-shaped, or the like. The U-shape, or V-shape, is presently considered to be the most practical and e Io preferred configuration for such a tube product.
In carrying out this invention, the deformation of the initially extruded tube, preferably of cylinder form, progresses in a gradual manner, by shaping means. That is, at least one side of the S" 15 tubular extrusion is increasingly depressed so as to condition the tubular extrusion for its lateral collapse into a reduced U-shaped, or V-shaped, cross-sectional form; thus providing a deformed tube, As pointed out above, this deformation is 10 conducted in the presence of controlled heat substntially below fluidity of the thermoplastic material and such that the plastic is deformed without adversely effecting its structural integrity, whether in its deformed condition or in its subsequently re-established initial condition.
Preferably, rollers are used to deform the initially extruded tube. In practice, the deformation is gradual, step by step, utilizing combined pairs of o th t «v~ 4 opposed shaping rollers. A feature hereof is the lateral collapse of the tubular extrusion over a forming rail, by means of opposed shaping rollers that embrace the forming rail. The finished product is then cooled to ambient temperature during and/or upon its delivery from the forming rail, as by means of a cooling trough. Heating and cooling is by meanrs of heat adsorption or radiant heating, and preferably e t by temperature controlled water baths or spray.
c b The present day commercial demand for this pipe •liner is a product ranging from 2 inches to 24 inches in diameter. The wall thickness will vary in proportion to diameter as circumstances require.
Accordingly, there will be variations in the process r5 steps involving the plurality of shaping means disclosed herein as shaping rollers and back-up roller, whereby at least one side of the tubular extrusion is deformed as required. That is, the number of shaping means and the step by step degree of deformation is variable, depending upon the size and wall thickness and material to be deformed. A feature of this method and apparatus is that the product is pulled out of the extruder and from the t deforming tool, for delivery to a storage spool, in a controlled manner, whereby the cross-sectional configuration of the deformed tube product is uniform and within specified dimensional tolerance. With respect to variations in size and tolerances, and especially with respect to larger diameter pipe 18 liners, it is an object of this invention to provide pulling traction on the tube during its process of deformation, and applied to the shaping means, disclosed herein as powered rollers. In practice torque is independently applied to the shaping and back-up rollers, so as to ensure uniform advance of the deforming tube product.
t The product herein disclosed is a thermoplastic 99 t pipe liner that is reduced from its initially Iextruded cross-section, so that it can be easily pulled inside a pipe line and then restored to its .9,4,.initially extruded cross-section. Assuming pipe to be round in cross-section, the outside diameter of the initially extruded and/or reformed liner tube is the same or slightly greater than the inside diameter of the pipe that receives it, so that the liner exterior comes into perfect interface contact with the pipe interior and preferably under slight circumferential compression. This interface contact of liner within and with the pipe eliminates any annulus therebetween, and so that the requirement of filling such an annultus is virtually eliminated. A featura of this liner is its thin-wall configuration i made of a thermoplastic such as polyethylene, nylon, Teflonim, ABS, or any other such plastic material, whereby the small loss of inside diiameter of the flow passage is largely compensated for by the exceptional flow coefficient within the liner made of such a thermoplastic material. F'or new pipe line projects, Ap 6 r expensive pipe materials such as stainless alloys can be substituted with ordinary steel pipe, and lined with this product liner, thereby realizing a cost saving of 1.5 to 2.2, together with the improved fluid tolerance properties of the plastic which can be selected to best advantage. Accordingly, pipe lines which are structurally sound need not be replaced, since this product liner can be installed and replaced as circumstances require.
t It The method and apparatus herein disclosed for "4 "the manufacture of this product liner involves the primary step of extruding thermoplastic tubing, and the secondary step of deforming the thermoplastic tubing. The primary step of extrusion involves 15 generally, an extruder that receives raw plastic material and delivers a tubular cross-section through a vacuum trough that controls the processing temperature and precise configuration of the tubular cross-section. The secondary step of deforming the )0 precise tubular Cross-section involves generally, a a multi-stage shaping tool that deforms the extrusion at controlled temperature and delivers it through a cooling trough a the finished product liner. The finished product liner is drawn from the secondary step by a puller that controls the linear speed of the production and maintains a constant wall thickness of the finished product liner.
The present invention also relates to an tt 1 ii :1 1 -i i 7 improved method and apparatus for installing the temporarily deformed pipe liner within a pipeline, expanding the deformed liner to its original cylindrical shape, taking additional steps causing the liner to conform even more precisely to the interior contour of the pipe, and flaring opposite ends of the liner into engagement with respective radially directed pipe flanges.
Before inserting the U-shaped liner in a pipe or ~pipeline section, a number of preparatory steps must be taken. For example, after accessing the pipe to be lined by existing man or access holes, or by digging new access holes, the pipe connections must be broken and the interior of the pipe or pipeline 15 section must be cleaned to remove all loose debris *and/or sediment therein. Subsequently, a pulling or pilot line must be threaded 'through the pipeline to enable the U-shaped liner to be pulled into the pipe from the downstream end. in this regard, throughout aQ this specification, "upstream" refers to that end of the pipe into which the liner is inserted, and 4,4,"downstream" refers to the end remote from the
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insertion end, in addition, the term "pipe" is used hereinafter to refer to single, individual lengths of pipe, as well as to a plurality of individual lengths join,'d together to form a pipeline or section of pipeline. in other words, "pipe" refers to any one or more 14'ngths of pipe to be lined in accordiance with this inv.,ntion. Moreover, regardless of the number of individual lengths of pipe to be lined, typically, the open ends of the pipe or pipes, which define the overall length to be lined, are provided with conventional radial flanges to facilitate attachment to adjacent pipe sections. Such flanges are also utilized in conjunction with the installation process and apparatus of this invention as explained in greater detail below.
SThe cleaning and threading operations may be |0 effected by a single brush pig of conventional design. At the same time, the brush pig is utilized 99 to pass the pilot or pulling line through the pipe.
To facilitate not only the pigging operation, but the liner insertion and expansion operations as' well, a .*iS7 '5 manifold, which opens into the pipe at one end and Y- which is closed by a removable flange at the other end, is applied to each end of the pipe, via the above-described radial flanges and fasteners such as bolts or the like, The inside diameter of the )0 process manifold is larger than the outside diameter of the liner, to aid in the removal of the manifold 9,449 after the expansion process, The same manifold size Sis also used as a "pigging station." Prior to i attaching the manifold at the upstream end, the brush pig is introduced into the manifold, and a pulling or pilot line is fed into a vent in the manifold and attached to the trailing end of the pig.
Once the manifolds are attached at either end of I t I I U_ I 9 the pipe, liquid or air is supplied behind the pig to drive it the length of the pipe. At the same time, a relief valve in the downstream manifold permits air ahead of the pig to be released from the pipe interior. Brushes attached to the front of the pig clean the interior pipe wall surface in a manner well understood by those skilled in the art.
When the pig and pulling lines have reached the downstream end of the pipe, the downstream manifold i" ,t I0 ,s opened and the pig removed. The pulling line is fit i then attached to a downstream winch or other suitable winding device.
9 At the upstream end, the upstream manifold is opened and the pilot or pulling line cut from the 0 4 t 15 supply reel, The line is then drawn through the open manifold and attached to a lead end of the U-shaped liner. The U-shaped liner may then be pulled from its own supply reel into the pipe via actuation of the downstream VWinch or other suitable winding 'A0 device.
It will be appreciated that depending on the ,length of pipe, the pressure available to push the pig through the pipe, and the tensile strength of the pulling line, a multiple stage process may be i$ required to thread the final pulling line through the pipe, For example, for long sections of pipe on the order of 2 miles or even longer, or Where there is a I (F f leak in the pipe, the pressure build-up in the pipe may not be sufficient to push the pig and, at the same time, pull a line or cable of the required strength through the pipe, In this case, a relatively light, so-called "fishing line" is initially threaded through the pipe by a relatively lightweight pig, followed by one or more increasingly stronger lines, drawn by larger pigs, until the final pulling line or cable is drawn through the pipe.
]0 Once the liner is drawn into the pipe via the downstream winch, it is cut to an appropriate length, such that a relatively short section of liner extends beyond either end of the pipe, to approximately the length of the pipe section itself plus upstream and downstream manifolds at either end.
Subsequently, packer/expander assemblies are introduced into the manifolds to seal the liner ends and to mechanically initiate expansion of the liner, Thereafter, fluid, preferably hot liquid from a ,0 closed boiler system, is supplied through one of the t*t: packer/expander assemblies and into the pipe to reheat the liner to a temperature which is to be Sabove the raw materials' crystallization point, for i texample, 260F?, when using Union Carbide Polyethylene raw material. During the reheating stage, an outlet valve in the manifold opposite that through which the hot liquid is supplied, is left partially open to allow the hot liquid to flow through, until the desired temperature is achieved. Once the liner has 6L or-
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reached a temperature above the raw materials' crystallization temperature, it will begin to assume its original cylindrical shape. At the sa.;e time, pressure within the liner rises, preferably to about 7 bars in a first pressurizing stage.
It is often the case, however, that the pipe 0. itself may not be perfectly round along its entire length and, there.ore, absent some further step, S" there may be annular or other pockets of air between 'G the liner and the inner pipe wall.
According to this invention, the outlet valve is adjusted so that the pressure within the liner is increased in a second stage to about 15 bars to cause the liner to conform more precisely to the inner t5 surface contours of the pipe. It is to be understood that the second-stage pressure application can be considered optional and will depend on the condition of the pipe to be lined as well as the wall thickness of the liner.
4n 4 Q0 Subsequently, the packer/expander assemblies are A removed after the hot liquid, such as water, is emptied from the pipe through a valve in the manifold. A calibrated pig is then introduced into tht upstream manifold to traverse the pipeline while the liner is still hot, and to apply a radially outwardly directed force about the circumference of the liner to squeeze out any remaining air between i v, I Ii -f
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I I V 12 the liner and pipe used thereby ensure even further conformance to the inner pipe wall, including weldments and other surface irregularities. This second pig is driven through the pipeline with cold water which tends to to "freeze" the liner in place.
Once liner expansion within the pipe is completed, the upstream and downstream manifolds are removed, and the liner ends are reheated and flared into contact with the blind flanges of the pipe, as t described in further detail below.
By this invention, pipes of between 2 and 24 inches in diameter, and as long as two miles or more may be fitted with a continuous liner to provide ideal corrosion protection in both new and existing corroded pipes.
Other Ldvantages of this invention include: 1. Structural characteristics of the pipe to be tot relined are preserved while the thickness of the U-Liner wall can be from 3.5 to 18 mm, depending on ,o design requirements, The minimal reduced inside idiameter will be compensated by the exceptional flow coefficient of the thermoplastic liner.
2. In the case of new pipe projects, the U-shaped liner can be used to avoid the need for expensive materials such as stainless steel or alloys
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13 for transport of highly corrosive products. In most cases, the flow inside the plastic liner will be more efficient than if stainless steel or alloy pipes are used.
3. Lining of internally corrodible pipes will provide operators with longer life in both new and repaired pipelines, without costly total replacement of pipe sections due to corrosion damage. This will effectively reduce repair and maintenance downtime S(0 and therefore greatly reduce production loss.
4. Since the U-shaped liner can be inserted in very long sections, this method simplifies the often difficult and much protested surface disturbance of right-of-way in environmentally sensitive areas or C*F 15 across urban concentrations of people and traffic.
t 5. Although the normal use life expectancy of the thermoplastic lining is up to one hundred years, unexpected damage can be repaired economically due to t the easy removal and replacement of the U-Liner and 10 its relatively minimal cost. The thermoplastic insert U-Liner will restore corroded pipes to original flow quality and eliminate further abrasion and corrosion damage to the steel pipe walls,thus Ssubstantially lengthening the economic life of the installation, 6. The process is simple, fast and cost i 1 1 1 1 3--11 14 effective, with minimum downtime.
In a preferred embodiment, the pipe liner is constructed of high density polyethylene (HDPE), which may be a Union Carbide DGDB-2480 Black 4865 compound meeting the requirements of ASTM 1248-81a for Type PE 34 Class C product. It is characterized by a high level of environmental stress cracking resistance and high strength. Nylon, TeflonN, ABS or any other such plastic material may also be utilized.
,4 The preferred HDPE liner material has been tested with over 280 chemicals that might be expected to flow through a pipeline and the following observations have been reported relating to the above identified HDPE which are particularly relevant to this invention: high resistance to H 2 S, CO 2 and NaCI; excellent for transporting gases; cross-linkable to handle products at high temperatures (250 0
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stability in aging; low roughness coefficient of 0.020; i .j-
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r l i does not retain deposits or sediments.
It will be appreciated from the foregoing that heat is used to relieve the stress in the liner in order for the liner to remain and to be frozen in its original cylindrical shape after processing has been completed. However, it has been found in accordance C" with another aspect of the present invention that this stress relief can also be obtained without a *temperature increase provided the pressure within the i0 pipe is maintained over a predetermined time period in order to relieve the stresses and ensure that the liner will remain in its generally cylindrical shape bearing against the interior wall of the original pipe. This discovery is particularly important in 15 the relining of pipelines which normally carry a ,fluid under pressure, gas or liquid, wherein the pressure of the fluid carried by the relined pipeline is sufficient to maintain the liner in its generally cylindrical shape.
10 In accordance with this aspect of the present cinvention, once the deformed liner is disposed in the pipe and the opposite ends of the liner are deformed at each end of the manifold as described previoualy, instead of heating the pipe, a pig is then inserted into the pipe to mechanically reform the liner into a generally cylindrical configuration. To accomplish this, the pig is preferably inserted at the downstream end of the pipe (although it may be 29 16 inserted at the upstream end) and a pressurized fluid, either a gas or liquid but preferably a gas, such as air, is introduced into the pipe behind the pig. Preferably, a backpressure is provided at the upstream end of the pipe. For example, the fluid behind the pig may be pressurized to about 25 to 150 while the upstream end of the pipe may be pressurized to about 5 to 40 p.s.i. As the pig travels through the liner, it reforms the liner into (O its original cylindrical shape. At the end of the lot* I travel of the pig, the liner is maintained under internal pressure for a predetermined time, for example, on the order of about 30 minutes. The i pressure is then relieved, the pigs and the manifolds are both removed, the opposite ends of the liner are flared, all as described previously, and service to c• the pressure fluid is restored, Particularly, such service is reconnected within a relatively short period of time, on the order of about 24 hours or LG less, so that the interior of the liner is repressurized by the pressure of the service fluid to .maintain the liner in generally cylindrical form bearing against the inner walls of the pipe.
S|Consequently, the pressure will ensure that the liner 5 conforms to the existing pipe and, over time, all stresses are relieved such that the liner will remain substantially cylindrical even when the service pressure is removed.
It will be appreciated that the foregoing t 0 if I rl 17 i described method of relining pressurized pipelines may be applied to non-pressurized pipe, provided the liner is maintained under pressure over a predetermined time. For example, maintaining the pressure for a time on the order of 3 to 4 weeks will in most cases ensure that the liner returns and is retained in its prior cylindrical configuration. For shorter periods of time, for example, less than one week, the liner may not return to and be retained in (0 its perfectly cylindrical configuration. However, sufficient stress is relieved in such shorter period of time such that the liner will be maintained generally cylindrical. The capa.ity to return to and to retain its generally cylindrical original configuration is a function of the diameter, material and wall thickness of the liner. Thus, the greater the diameter and/or thickness, the greater the time period the liner should be maintained under pressure in order to return to and to be retained in its X0 original cylindrical configuration. The converse is also true.
The invention as described herein has applications to many types of pipeline, including Swater and mud injection; oil and gas; vapors and fumes; saltwater; utility sewage and drainage; gas gathering and distribution, etc.
There is provided in accordance with a preferred embodiment of the present invention a method for 3J 31 31 18 producing a deformed pipe liner of tubular cross-section having an outside diameter to fit into a pipe line and formed of plastic material for subsequent insertion into a pipe line and then reformed to the cross-section wherein the improved method is characterized by firstly collapsing the tubular cross-section at a deformable portion thereof by folding it by depression diametrically toward an opposite side portion thereof along a plane of IO bilateral symmetry about which opposite side sections of the tubular cross-section bend into double-wall configurations with the fold juxtaposed to the opposite side portion of the tubular cross-section, secondly collapsing the opposite side sections of 15 double-wall configurations laterally toward the plane of bilateral symmetry by bending the double-wall configuration of the opposite side sections, thereby 60 'reducing the cross-sectional configuration without elongation and for insertion into the pipe line and XO reformation therein to its initial tubular cross-section to fit within the pipe line.
There is further provided in accordance with a preferred embodiment of the present invention an apparatus for producing a deformed pipe liner having a ttubular cross-section and formed of plastic material for subsequent insertion into a pipe line and then reformed to the extruded cross-section to fit the inside diameter of the pipe line, wherein the improved apparatus is characterized by at least one i n 1 f 4 19 revolvable back-up roller disposed on a horizontal axis parallel to the axis of and in opposition to at least one revolvable shaping roller, the back-up roller having a concave spool-shaped periphery centered at a plane of bilateral symmetry to engage a back-up portion of the tubular cross-section, the shaping roller having a convex fold initiating and fold shaping perimeter at the plane of bilateral symmetry to depress a deformable portion of the 1o tubular cross-section diametrically toward the back-up portion thereof and along the plane of bilateral symmetry about which opposite side sections of the tubular cross-section bend into double wall configurations with a fold thereof juxtaposed to the opposite back-up portion of the tubular cross-section Sand a pair of laterally positioned revolvable shaping rollers disposed on vertical axes at opposite sides Sof the plane of bilateral symmetry and each having a Sf concave curvilinear periphery to engage and further SO depress the double-wall configrations of the side sections laterally inward toward the plane of bilateral symmetry by bending the double-wall configurations of the opposite side sections, thereby S, reducing the cross-sectional configuration of the c15 tubular cros-section and further collapsing the opposite side sections thereof from a top dead center position thereof coincidental with the plane of bilateral symmetry.
A further preferred embodiment of the present i- redcin t ti i
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invention provides a process for installing a hollow cylindrical thermoplastic liner in a pipe wherein the process is characterized by the steps of altering the cross-sectional shape of the liner to reduce the S cross-sectional dimension thereof at a shape memory activation temperature of about 160-180 0 F, pulling the altered liner into the pipe such that the tubular liner extends beyond opposite ends of the pipe, reheating the liner to the memory activation S 10 temperature to cause the liner to return to the 8 cylindrical cross-sectional size and shape and, subsequently, increasing pressure within the liner to cause the liner to conform to interior contours of the pipe.
A still further preferred embodiment of the invention provides a process for installing a thermoplastic liner in a substantially round pipe having inside and outside diameters wherein the r, process iq characterized by forming at a first O~t a0 elevated temperature a thermoplastic liner having a cylindrical shape and an outside diameter larger than the inside diameter of the pipe, temporarily deforming the cylindrical liner at a second elevated temperature to an altered cross-sectional configuration which reduces the cross-sectional dimension of the liner by about 25%, cooling the liner to ambient temperature, inserting the liner in the pipe, reheating the liner to at least the second elevated temperature to cause the liner to return to KY
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21 the cylindrical shape and applying additional expansion forces to the liner to substantially conform the liner to the pipe.
A still further preferred embodiment of the S present invention provides a process for installing a thermoplastic liner in a pipe comprising the steps of providing a hollow generally cylindrical liner formed of thermoplastic material, altering the cross-sectional shape of the liner to reduce the 1, 10 cross-sectional dimension thereof, disposing the o altered liner into said pipe such that the liner Sextends beyond the opposite ends of the pipe, mechanically reforming the liner to cause the liner to return to its generally cylindrical cross-section and bear against the inner walls of the pipe and Spressurizing the interior of the liner from end to end and for a predetermined time to maintain the liner against the interior walls of the pipe and to relieve the stresses in the liner tending to cause 20 the liner to return to its altered shape.
Qther objects and advantages will become apparent from the detailed description of the invention which follows.
BRIEF DESCRIPTION OF THE DRAWINGS FIGURE 1 is a block diagram illustrating the method of producing an extruded plastic pipe liner I I 1 22 for restoration to its initially extruded cross-sectional configuration; FIGURES 2a, 2b, 2c, 2d and 2e are sectional views of the extruded pipe liner in its sequential of deformation, aind showing in phantom line the cylindrical configuration of the finished linler for comparison of the daformation in each figure; i FIGURE 3 is an enlarged longitudinal sectional view of the deformer apparatus which performs the to method herein disclosed to deform extruded thermoplastic tubing; FIGURES 4 through 9 are enlarged detailed sectional. views taken ,jubstanti ally as indicated. by lines 4-4, 5-5, 6-6, 7-7, and 9-9 in FIGURE 3; FIGURE 10 is a schematic side view showing a pilot line being pulled through a pipe section to be lined in accordance with the invention; FIGURE 11 is a schematic, side view illustrating a further step in a pipe lining process wherein a 74 q b. eavier gauge pulling liei einq pull~ed through 4 the pipe section to be linedl FIGURE 12 is a schematic top view illustrating a temporar~ily deformed pipe liner being pulled through a pipe section in accordance with the invention; Afti -I i fi~i r
'S
*I ac 9 .9, 9 4, 94 4 *c 9 9c *r 4: 4. 4 4( 9 9 49 94 S 9c FIGURE 13 is a cross-sectional view of a pipe section and associated liner; FIGURE 14 is a cross-sectional view of a temporarily deformed pipe liner in accordance with the invention; FIGURE 15 is a partial, perspective view illustrating a temporarily deformed liner within a pipe section to be lined; FIGURE 16 is a schematic side view illustrating 10 the commencement of a pipe liner expansion process in accordance with the invention; FIGURE 17 is a side elevation of a packer/expander assembly for use in the subject invention; FIGURE 18 is a partial side view of the device illustrated in FIGURE 17; FIGURE 19 is a side schematic view illustrating a fully expanded pipe liner in accordance with the invention; FIGURES 20-22 represent a schematic progression illustrating the formation of a radial flange on a pipe liner in accordance with the invention; 4 4 iri FIGURE 23 is a top sectional view illustrating a flaring tool in accordance with the subject invention; FIGURE 24 is a side view of a tool element for use with the flaring tool illustrated in FIGURE 23; FIGURE 25 is an end view of a pipe lined in accordance with the invention; and FIGURE 26 is a side schematic view illustrating i a plurality of aligned pipe sections with individual *pipe liners in accordance with the invention, 9 49 94 9 S 10 DESCRIPTION OF THE PREFERRED EMBODIMENTS i i, Referring now to the drawings, this invention is concerned with lining new and old pipe lines with a 44 deformed tube that is pulled into the pipe line and then reformed to tightly fit therein. The tube can be made of any suitable material which will collapse t: and subsequently return to its original cross-section, a plastic, In practice, the pipe liner is a thin-walled plastic sleeve extruded 4. 44. in continuous lengths and later inserted into pipe 0 lines for internal protection; for example to protect new pipe lines and to reconstitute deteriorated pipe lines as well.
Accordingly, the pipe liner L as it is disclosed herein is initially extruded so as to have an 45 1 _i I i I I I I I r i, l Y-ir~~ -il. I ii^i:i~ 4MI J-
U
e3'terior diameter at least as large as the interior diameter of the pipe into which it is to be inserted, and preferably1- slightly in excess of said pipe diameter in Order that the tubular pipe liner L is Sunder slight circumferential co~mpression when it is in operating position in the pipe line. A feature of this invention is the deformation of the tubular pipe liner L, to decrease its cross-sectio~n configuration for storage and to facilitate itLs insertion into a to pipe. That is, the original cylinder cross-section of the pipe liner L is collapsed and later reptored, all without destroying its dimensional properties.
Therefore, the circular configuration of the pipe liner L is not stretched, ;even though the material is Splastic and subject to flow. In, other words, the or.ginal cylindrical cross-section properties of the initially extruded pipe liner L, are preserved in its deformed condition which enables _,ts insertion into pipe lines and for its subsequent reformation into Its original cylindrical cross-section. The characteristic feature of this invention is that the initially extruded thermoplastic pipe liner L is shapeQ and thereby deformed without elongation, whereby its dimensional propertieg necessary for are retained.
4Referring now -to the deformation of pipe liner L as shown in Figu.res 2a through 2e of the drawings, the initially extruded configuration is cylindrical, having inner and outer diameter walls 10 and 11. As
_J
26 shown, there is an upper back-up section 12 and a lower deformable section 13. The deformation is bilaterally symmetrical and disposed about a vertical plane a of symmetry and about which the tube formation is collapsed by means of bending and folding. Accordingly, there are opposite side sections 14 and 15 which are established by a center fold 16 that inverts the lower deformable section 13 upwardly into juxtaposed relation to the inside IO diameter 10 of the back-up section 12. Therefore, each side section is comprised of a side wall depending from top dead center of the tube form and bent inwardly so as to continue upwardly to the center fold 16. It is significant that the two side sections 14 and 15 are thereby collapsed into double wall configurations which are further collapsed inwardly toward the center plane a of symmetry as clearly shown in Figure 2e which is the desired product formation.
t r O Referring now to Figure 1 of the drawings, the entire method of tube formation and deformation is illustrated in its general form. As shown, there is an extruder means E followed by a cooling means C1 that delivers the tube form into a deformer apparatus D which performs the product deformation process.
Following the deformation process, the product is then delivered through cooling means C2 so as to establish it at ambient temperature for delivery through a puller means P and onto a storage spool S 1 1 11--~1 i 27 or the like. The extruder means E is state of the art and receives the raw thermoplastic material and forces it through an extrusion die 17 at, for example, 3500 to 440 0 F using heating means 18 to attain that temperature. The cooling means Cl is state of the art, and preferably a vacuum cooling means supported by a vacuum cooling unit 19 and reducing the tube form temperature to, for example, 260 0 F. The deformer apparatus D is subjected to heat >0 control means H that maintains this necessary deformation temperature of, for example, 260 0 F. The S. cooling means C2 is state of the art and reduces the tube form temperature to ambient, and it is supported, for example, by a cooling tower 20 or the )5 like. During the cooling period, the shape of the deformed liner is to be maintained until the pipe reaches an ambient temperature. This shape can be maintained by outside pressure such as rollers, caterpillars, or straps, or maintained by an internal vacuum, The means Cl and C2 include pump means for b, water recirculation, and it is to be understood that the aforementioned temperatures can vary as Scircumstances require. Puller means P is also state S of the art and draws the finished deformed tube S 5 product from the preceding apparatus, its pulling force being controlled so as not to stretch or compress the tube form in the process of its deformation, and thereby controlling its wall thickness.
k| a _L i Referring now to the method or process of deforming a continuously extruded tube form of plastic material, the steps thereof are sequentially as follows: firstly, a cylindrical tube form is extruded as shown by phantom lines in Figures 2a through 2e, thereby establishing a uniform wall section, and preferably of cylindrical configuration. The top semi-circular portion, namely the back-up section 12, is supported and the fold 16 is impressed at bottom dead center of the tube form r* in alignment with the center plane of symmetry and progressing upwardly and into juxtaposed relation to r the inside wall 10 of the tube form at top dead center thereof. It is to be understood that the ~~i5 deformation process can be performed on any angle, .such as prescribed above on a dead center bottom, but also from its side, top or any other angle. In this process of deformation, the opposite side sections 14 "and 15 are turned and/or bent inwardly at their lower 0 extremities 21 and 22, so that the walls thereof continue upwardly within their respective inside walls 10 and to the fold 16 (see Figures 2a through 2d).
The fold 16 is formed by bending the tube form 5 inwardly at bottom dead center thereof for collapse along the center plane of symmetry, Simultaneously with this collapse, the lower extremities 21 and 22 of the side sections 14 and 15 are also inwardly bent as above described. In practice, collapse of the 1 U 29 d tube form is preferred in a multiplicity of steps, in ti order to conform gradually to the changing configuration of the tube form and without elongation of its cross-sectional configuration. However, it is §to be understood that collapse as thus far described can be accomplished in a single step, for example in small diameter tubing. As shown, however, there are four steps of collapse along the center line a of symmetry, and each of which has back-up against the 0 top section 12, it being the bottom section 13 that is deformed.
The first step of collapse shown in Figure 2a initiates the fold 16 by bending and commences to bend the lower extremities 21 and 22. The succeeding three steps of Figures 2b and 2c and 2d progressively and increasingly bend and move the fold 16 close to the inside wall 10 at the top dead center of the tube form and simultaneously increasingly and progressively bend and move the lower extremities 21 Cj and 22 upwardly as shown. Thus, the tubular cross-satction is reduced in its sectional confiluratt on.
Referring now to Figure 2e of the drawings, a final step of collapse is performed by bending the 2opposite side sections 14 and 15 inwardly toward the center plane of symmetry, in order to reduce the arcuate configuration of said two side sections and so that they occur within the radius or outside 44 diameter of the initial tube form, and so as to clear within the inside diameter of -the pipe line into which the ultimate pipe liner L is inserted. A feature of this final collapsing step is bringing together the two lower extremities 21 and 22 into juxtaposed relation to the center plane of symmetry, and preferably closer together than the continuing tube walls upstanding therefrom to the bends of fold 16.
Referring now to the preferred form of apparatus for deforming a continuously extruded tube form of at' .plastic material, see Figure 3 and the following C a 94 sectional views Figures 41 through 9. It will be observed that there are five collapsing steps performed thereby, four incrementally progressive steps of folding the bottom '3ection 13 of the tube 4 form upwardly along the ceriter plane of symmetry, and a fifth step of laterally inward collapse. Each and all of these five steps involves bending, and is 2essentially if not completely devoid of stretching or elongation of the tube wall of the pipe liner L, in its transverse cross-section. Each step of collapse is performed by forming means, preferably in the form K of shaping rollers R1., R2, R3 and R4, followed by tshaping rollers Si and.S2. It is these rollers which increasingly and progressively collapse the extrud~ed tube form, In practice, the shaping rollers R1-R4 are lowermost, there being back~-up rollers B1., B2 and B3 to support the tube form as it is impressed upon PrT 31 by the said rollers Rl-R4. As shown, the rollers Rl-R4 and B1-B3 are on spaced and parallel horizontally disposed and transverse axes.
Back-up roller BI is disposed over the shaping $roller Rl (see Figure 4) and is characterized by its concaved spool-shape 25 at the center plane of symmetry and conforming to the substantially semi-circular back-up section 12 of the tube form.
Back-up roller BI has opposite flaring side flanges i Q that embrace the initial formation of the side sections 14 and 15 of the tube form.
Shaping roller RI (see Figure 4) is characterized by its c &onvex fold initiating and shaping perimeter 27 at the center plane of symmetry Lto depress the tube form wall upwardly at bottom dead center. Shaping roller RI has opposite concave sidie flanges 28 that embrace the initial formation of the lower extremities 21 and 22 of the side sections 14 and 15. The perimeters of roller flanges 26 and 28 ~are closely related so as to capture the tube form therebetween.
Back-up roller B2 is disposed over and intermediate shaping rollers R2 and R3 (see Figure 3) and is characterized by its concaved spool shape at -the center plane of symmetry and conforming to the substantially semi-circular back-up section 12 of the tube form. Back-up roller B2 has opposite flaring I. It 32 flanges 36, to a lesser extent than that of roller 51, to embrace the formation of the side sections 14 and 15 of the tube form.
Shaping roller R2 (see Figure 5) is by its convex fold shaping perimeter 37 at the center plane of symmetry to further shape the tube form wall upwardly along said plane of symmetry. Shaping roller R2 has opposite concaved side flanges 38 that embrace the lower extremities 21 0C and 22 of the side sections 14 and 15. The perimeters of roller flanges 36 and 38 are somewhat spaced and guide the tube form therebetween, Shaping roller R3 (see Figure 6) is characterized by its convex fold shaping perimeter 47 at the center plA~ne of symmetry to further shape the tube form wall upwardly along said plane of *symmetry. Shaping roller R3 has opposite concaved side flanges 48, of lesser extent than roller R2, 4 that embrace the lowtir extremities and 22 of the ~side sections 1.4 anO 15. The perimeters of roller flanges 36 and 48 aYre somewhat spaced and guide the tube form therebet~een.
Back-up roller B3 (see Figure 7) is disposed over shaping roller R4 and Is characterized by its spool-shape 55 at the center plane of symmetry and conforming to the substantially semi-circular back-up section 12 of the tube form,
I
33 Back-up roller B3 has minimized side flanges 56 that embrace the side sections 14 and 15 of the tube form.
Shaping roller R4 (see Figure 7) is characterized by its most sharply convexed fold shaping perimeter 57 at the center plane of symmetry to still further shape the tube form wall along said plane of symmetry. Shaping roller R4 has opposite concaved side flanges 58, of' still lesser extent 4-han roller R3, that embrace the lower extremities 21 and (0 22 of the side sections 14 and 15. The perimeters of roller flanges 56 and 58 are closely related so as to capture and guide the tube form therebetween.
The fifth and final collapsing step is performed by a pair of laterally positioned shaping rollers S1 and S2 di.sposed at opposite sides of the tube form as it emanatez from shaping roller R4 (see Figures 8 and Rollers Si and S2 are to reduce the arzcuate cross-section~ of back-up section 12 of the tube form, as shown. Accordingly, the rollers Si and S2 are o disposed on spaced and parallel vertical axes and are characterized by a concave spool shape 60 of curvilinear configuration increasing in curvature from top dead center, each roller, from the initial full radius of the tube form to the smaller radius of ~the lower extremities 21 and 22. The rollers Si and S2 have top and bottom flanges 61 and 62 which are peripherally juxtaposed so as to completely capture the finally collapsed and deformed tube form, thereby d 47 I- 34 establishing the product pipe liner L.
In accordance with this invention, and as best illustrated in Figures 8 and 9 of the drawings, the tube form of pipe liner L is finally collapsed onto a rail R disposed between the shaping rollers S1 and S2. The rail R is of a cross-sectional configuration to conform with the inside walls of the side sections 14 and 15 and of the lower extremities 21 and 22.
Accordingly, and as clearly shown, the final iG cross-sectional configuration of the pipe liner L is established. In practice, the rail R has sliding engagement with the tube form and is of substantial longitudinal extent so as to enable a reduction in temperature and firming up while being held in the 5 required cross-sectional configuration. Note particularly the hourglass cross-section of the rail R that accommodates the aforementioned collapsing of the lower extremities 21 and 22, bringing them closer together in relation to the center plane of symmetry ,0o than the upstanding inner walls extending to the bends of fold 16. In practice, rail R is optional depending on the shape to be defined. If a precise curvature 16 is necessary, the rail R will aid in keeping such a shape. This rail R, for example, S 5 would be necessary for the bud fusion of the deformed pipe.
From the foregoing, it will be observed that the shaping of the tube form is gradual and progressive hiS .4 ii_
I-F--
a0 *4 0i 0 0a ad 0# a 0 at 4 a to a4 a 0* (see Figures 3 and 9) and from Figure 1 it will be observed that the temperature control is involved, and the preferred material involved is a thermoplastic. Accordingly, and as best illustrated in Figure 3 of the drawings, there are water nozzles that dispense tempered water so as to maintain the temperature of, for example, 210°F in order to soften the plastic material and to ensure its bending properties. Other heat sources such as hot air or radiant heat can be incorporated to obtain the desired temperature of the pipe, which is to be above the raw materials' crystallization point. Nozzles disseminate hot water into the area of the shaping rollers R1 through R4 and Sl and S2. Thus, the tube 15 form is made plastic so as to be shaped and bent into the desired deformed condition. Following the final shaping of the tube form and its sliding engagement on the rail R, the shape enabling temperature of the plastic tube form is reduced to ambient by water 2O nozzles 71 that dispense tempered water at lower temperature so as to cool the finished pipe liner L to, for example, 70°F, all as shown in Figures 1 and 3 of the drawings. As shown in Figure 3, the tempered water is collected in a sump or pan 72 for its recirculation as shown in Figure 1. The cooling means C2 reduces the tube form to ambient temperature on or passing into delivery from the rail R.
As shown in Figure 3 of the drawings, the rollers B1-B3, R1-R4 and Si and S2 are free to turn -1 ~icc- r 1
F
t Ii i LI IC I~C i
CI-
36 on bearings 73 and thereby enable forward mction of the tube form through the apparatus as described.
However, as thin-walled large diameter pipe liners L are processed, it becomes necessary with some to assist movement of the tube form therethrough. Accordingly, torque means M in the form of motors M, electrical or hydrauliq, provide the assist required (see Figure It is to be understood that anti-friction bearings 73 are provided with shafting 74, all as is shown throughout the drawings.
From the foregoing, it will be understood that a tubular pipe line L is provided that is reduced in cross-sectional configuration so as to be readily inserted into pipe lines and then reformed -to its initially extruded cross-sectional configuration, whereby it properly fits into the pipe line for which it is designed, all as differing circumstances ,*require, To insert the liner L into a pipe line and roforrm it, and with reference now to Figures 10-26, a cylindrical section 80 of pipe to be lined is shown.
The pipe is formed with radial flanges 82, 84 at 4,44 either end to enable connection with adjacent pipe I $sections In a conventionail manner.
While the pipe lining procedure is shown primarily in schematic form, it will be understood 37 that the pipe may be lined above ground or, in situ, underground or underwater. In any or all of the above cases, it may be necessary to disconnect the pipeline at selected, longitudinally spaced access and, if continuous pipeline flow is required, splice in a bypass section between pipe sections on either side of the section to be lined. This bypassing or splicing procedure forms no part of the present invention and need not be described further.
Before commencing the lining operation, the pipe 0 section should be inspected to determine its ability i to withstand pressures applied during the lining operation.. Of course, if the pipe is damaged, corroded, etc. to the point of not being able to withstand such pressures, then the pipe section in question must to be replaced rather than lined, The interior of the pipe 80 may be cleaned by a conventional brush p-ig 86 designed to traverse the **pipe interior with brushes extending radial~ly into -~contact O'th the interior pipe wall, to effect removal of loose material, residue, sediment, and the like which. might otherwise negatively impact, the lining process. Once the pig 86 is introduced into the upstream end of pipe 810, upstream and downstlream manifolds 88 and 90 are attached to the pipe flanges 82, 84, respectivel.y. To facilitate this connection, the manifolds are provided with abutting .flanges 82', 84' and connection is achieved via bolts or other 38 suitable fasteners in conjunction wilth aligjned apertures (Figure 25) in the respective flanges, A pulling or pilot line 92, fed firlm a tnel 4 through a vent bole 96 in the manifold 88, is to the trailing end of the pig 86 before closure of the upstream manifold 88.
The upstream maxr'fold 88 has a closed end 98 which comprises a removable plate, and in which is mounted an inlet valve 1.00. In -this initial pigging operation, the valve 100 is connected via conduit 102 to a pressurized air or liquid source 104, The downstream manifold 90 is also provided with an 'end plate which mounts a relief valve 106. A pressure gauge 108 monitors pressur~e within the pipe, Pressurized air or water is introduced through a valve 100 into the pipe behind the pig 86, so as to push the brush pig And pulling line 92 through the pipe 'to the downstream end thereof, During this pigging operation, relief valve 106 is set at about 100 psi to ensure proper degassing of the pipe as the pig moves to the downstream end of the pipe, When the pig 86 reaches the downstream end, and move6 Into the manifold 90, the interior pressure of the pipe is gradually released, manifolds 88 and 90 are opened, and pig 86 removed, Thereafter, line 92 may be drawn out and subsequently f'astened to an associated w.Encl or reel 110 as shown in Figure 11.
THE CLAIMS DEPINING TIM~ MNENTION ARE AS VOLLOWS., I. 39 With further reference to Figure 11, the pipe section 80 is shown with manifolds 88 and 90 opened at their remote ends and with an initial lightweight fishing line 92 connected to a heavier gauge pulling or pilot line 112. Lines j2 and 112 are pulled through the pipeline 80 by winch 110 located adjacent the downstream end of the pipeline 80 and manifold The pilot line 112 is unwound from a reel 114 at the upstream end of the pipeline section. As /0 indicatrd earlier, the requirement for progressively strong(- pilot or pulling lines is necessitated only if the pipeline section to be lined is of great length or, if there is an inability to build up sufficient pressure, by reason of leakage for iS example,'in the existing pipeline, to push the pig 86 and associated fishing or pilot line through the pipe section. Once the appropriate gauge pulling line is drawn through the pipe section 80, it may be cut adjacent the upstream manifold 88 and thereafter attached to the temporarily deformed U-shaped liner L, as more clearly illutrated in Figure 12. The pulling line 112 is cov nected to the U-shaped liner L by a suitable grippinq arrangement shown in schematic iorm at 116 in Figur 12. Preferably, the gripping 245 means I16 is of the radial expansion type so as to prevent damage to the end of the liner. As also 4 4' illustrated in Figure 12, the U-shaped liner L may be unwound from a storage or supply reel S which is located adjacent the upstream manifold, It will be 0 appreciated that depending on the diameter of the 52 tubul.ar cross-section.
3. A method as set forth in Claim 1, wherein the originally extruded liner L, the liner may be temporarily deformed at the factory and shipped in continuously wound reels S or, where the diameter of the originally extruded pipe is so large as to make such predeformation and shipment impractical, mobile deforming apparatus may be provided at the site for deforming the liner L in situ and pulling it through the pipe section to be lined in one continuous operation. A mobile deforming apparatus may be 1 provided constituting the same principle as the apparatus disclosed in this invention, with the exception that the heating device before deforming will be extended to raise the temperature of the now ambient round pipe to past its crystallization point. In other words, the benefit of an already warmi pipe (out of the extruders' vacuum trough) is not available working with a mobile deforming tool.
Figure 13 illustrates a cross-sectional view of pipeline section 80 with the liner L in its finally expancied form. This is to contrasted with the cross-e8ectional view of the pipe liner L. in Figure, 14 which illustrates It in its tempor~arily deformed U-shape. In Figure 15, a perspective view illustrates the temporarily deformed U-shaped li'ner L ZS after it is pulled through the pipe section 80 to be lined. Turning now to Figure 16, it will be noted initially that the liner L exten~ds approximately to the open ends of the manifolds a and 90 to not only facilitate the *xpansion ptocesci but also to leave -53 Insertion into the pipe line and reformation therein substantially to its initially tttthwsi'_ i: I r I 1
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*i 14 I. II 1t** I I
III
f f I
I
$4 S
I
-ii Il x 41 sufficient liner to form radial flanges in a manner to be described in greater detail below.
In Figure 16, there is schematically shown a representation of the initial expansion of the liner L within the pipe 80. Once the liner is properly positioned, a pair of mechanical expansion/packer assemblies are inserted into the liner from either end of the upstream and downstream manifolds 88, The packer/expander assemblies 120, 122 are identical tO in every respect and, therefore, only one need be described in detail, As best seen in Figures 6-18, the downstream packer/expander 122 assembly includes an inlet conduit or manifold 124 operatively connected to a closed boiler 126 through which hot 15 liquid may be introduced into the liner via valve 128. The temperature of the liquid is monitored by a conventional gauge 130, while the pressure within the liner is monitored by a conventional pressure gauge 132. Inlet pipe 124 is connected via pipe extension 0 124' to a cylindrical packer assembly 134 consisting of conventional packing rings which are sized to seal off the liner relative to the manifold 90 to prevent any escape of liquid from the liner through the manifold. A cylindrical wedge-like expander 136, provided with a tapered surface 138, extends forward of the packer assembly and serves to force the liner end back into a cylindrical shape, as best seen in Figure 16. A similar arrangement is pi>vided at the upstream manifold 88 so that the liner L is initially _i I~Fl i I :i 54 comprising: at least one rotatable back-uD roller dicnnatd nn an 42 expanded mechanically at both ends in the above described manner. The expander 136 is provided with an internal bore 140 (Figures 17 and 18) which operatively connects to the inlet conduit 124 and closed boiler 126. It will thus be appreciated that expander 136 only initiates the expansion process, while facilitating introduction of hot liquid through the bore 140 -nd into the liner L.
y Once the packer/expander assemblies 120, 122 have been positioned within the manifolds 88, respectively, so that flanges 142 abut corresponding flanges on the manifolds 88, 90, hot water is Sintroduced from the source 126 into the interior of the liner. Because the system is closed, the hot water may be raised to high temperatures without the creation of steam and, in this initial stage, the hot water is introduced into the liner so as to raise the temperature of the liner above its crystallization I. point. In the temperature raising stage, a relief SI valve 144 in the packer/expander assembly 120, allows hot water to flow continuously through the liner, at Sa first pressure of about 7 bars. It will be appreciated that the period of time required to Sreheat the liner to its shape memory temperature at the first pressure will depend on the diameter and length of the pipe to be lined.
Once the liner has been heated to 1600, the U-shaped memory of the liner is erased and the liner 55 the back-up roller having a curved concave spoolshaped PeriDherv centr_d Ata nin _P_ I- -I 43 tends to assume its original cylindrical shape.
However, as previously mentioned, because the interior wall of the pipe 80 may not be perfectly round, the now cylindrical liner L may not conform exactly to the inner surface of the pipe which may be warped, particularly over extended distances.
Accordingly, the pressure inside the liner is raised in a second stage to about 15 bars to expand the liner L intc substantially exact conformance with the Il interior surface of the pipe 80, as illustrated in Figure 19. The process manifold is further equipped with an air outlet (air leak) that enables the air or liquid which might have been trapped between the liner and the original pipe to escape. This is another reason why the manifold is slightly oversized as compared to the O,D, of the liner.
Thereafter, valve 128 is closed, hot water supply 126 disconnected, and the hot water within the pipe is emptied. The packer/expander assemblies 120, Or 122 are then withdrawn, It is a further feature of this invention that, while the liner is still hot, a conventional expansion pig, having a diameter substantially identical to the inside diameter of the s expanded liner, is introduced into the pipe 80 and is pushed through the pipe section applying a radial force to the liner so as squeeze any remaining air from between the pipe and liner so as to conform 100% of the liner surface against the interior surface of the pipe. The pig is preferably driven by a supply -56as set forth in Claim 16, and including means for heating tho f illay. V 1 4. 44 of cold water which more or less "freezes" the plastic into final form behind the pig, eliminating all air spaces between the liner and the pipe section.
While the expansion stage has been described with reference to the introduction of heated fluid from source 126 at the downstream side of the pipe via packer/expander assembly 122, it will be appreciated that source 126 may be operatively S. /O connected to the upstream assembly 120 as well. In this regard, manifolds 88, 90 and assemblies 120, 122, including conduit 124 are provided with the necessary inlets, outlets for monitoring devices, relief valves, and the like so that, in effect, they are interchangeable.
Turning now to Figures 20 through 22, a schematic progression of steps involved in the liner end flaring process is illustrated. Thus, Figure 22 shows the expanded liner L extending beyond pipe G0 with the manifold 88 removed. Typically, the liner wil,1 be trimmed in accordance with predetermined and calcu'lated data establishing the length of liner requirced to produce a given size radial flange for pipes of various diameters. Once the liner is trimmed, a first flaring stage commences wherein the liner end is heated, Ly an air gun for example, to about 180-200 0 F, and flange 148 is partially formed at an angle of about 50 to about 70°, relative to
(II
57 plane of bilateral symmetry.
I. l horizontal, as shown in Figure 21. The specific angle will depend on factors such as the diameter of the pipe, the flange length, and so on. Once the initial flare is formed in the liner end, the latter .~is quickly cooled and then reheated to about 180-200 0 F. In a second flaring stage, the partially flared end is further deformed into engagement with pipe flange 82 to form radial flanges 148 as illustrated in Figure 22, after which the liner is lo again quickly cooled.
*1 *~Figure 23 illustrates an exemplary flaring tool *for carrying out the first and second flaring stages as described above. A manually operated screw jack 150 is fastened at at least two locations, preferably 180' apart, about the pipe flange 82. Thus, a pair of heavy duty bolts 152 extend between bolt holes formed in the flange 82 and a cross bar 154. Bar 154 is provided with a threaded aperture 156, intermediate the ends thereof, for receiving a threaded jack member 158 which mounts a flaring tool 160, a packing assembly 162, a washer 164 and a nut 166 on one side of the cross-bar 154, and a handle 168 on -the other side of the cross bar, Rotation of V handle 168 in a clockwise direction will result in 'IS flaring tool 160 entering the liner end to flare the same in a first flaring stage as previously described. The packer assembly 162 is -utilized to prevent the liner L from creeping into the pipe during the flaring operation. After completion of wherein said heating means comprises a plurality of fluid 46 the first flaring stage, tool 160 is removed from jack 158 and is replaced by a second stage flaring tool 170, shown in Figure 24. This second stage tool is no more than a bored, cylindrical block which S flattens the partial flare into full engagement with the pipe flange 82. In this regard, Figure 25 shows in an end view, the liner L in its finally flared and expanded configuration within the pipe In further connection with the first and second 10 flaring stages, it will be appreciated that the speed with which the flaring tools are brought into engagement with the liner end or ends must be correlated to the pipe diameter, temperature, etc. to prevent damage to the end or ends' Thus, the flaring tools do not engage the liner end or ends, until the ttemperature, monitored by conventional means, reaches
I*
the predetermined level. In addition, during the flaring stages, the tools remain in full pressure engagement with the liner end or ends during the respective cooling steps.
4 It will be further appreciated that the screw jack 150 may be hydraulically actuated, particularly 'd for larger diameter pipes.
In Figure 26, there is illustrated a plurality of adjacent pipes 80, each having an individual liner L applied in accordance with the above described process. The formation of radial flanges 148 on each i 47 liner section results in a continuous interior lining P with no pipe exposure to the materials flowing through the pipeline. This of course is an alternative to introducing a single continuous liner through a plurality of single pipe sections, but with similarly effective results.
For those pipes typically in service under pressure, it has been found that it is not necessary to heat the liner to its crystallization point in Io order for the liner, after being reformed, to remain frczen in its original generally cylindrical shape, provided the liner is maintained under pressure for an extended period of time. That pressure may, in accordance with the present invention, comprise the pressure of the liquid in the pipe when in normal servic. Consequently, after the interior of the pipe to be lined is cleaned by the conventional brush pig 86, the manifolds 88 and 90 are in place and the deformed liner is inserted into the pipe, the liner s l can be mechanically reformed to its original, generally cylindrical shape with the use of a pig and applied pressure. Consequently, in this embodiment, the ends of the manifolds are initially deformed as previously described and the pig is inserted, I$ preferably at the downstream end. The pig may be conventional and may comprise a medium density foam.
Upon initial insertion of the pig, the ends of the pipe are closed and a fluid under pressure, for example, air, under a pressure between about 25 and 18 938/88
VACUUM
48 150 depending on the pipe size and length, is introduced behind the plug at the downstream end.
Additionally, a back pressure or vacuum pressure is provided at the upstream end of the pipe, for example, on the order of about 5 to 40 again depending upon the length and size of the pipe.
Because of the differential pressure applied to the pig, the pig advances from the downstream end of the pipe to the upstream end, mechanically reforming the iG pipe to its generally cylindrical configuration as it S' t moves between those ends. Upon arrival at the upstream end, the pressure is maintained behind the pig throughout the length of the pipe and liner for a predetermined time interval, for example, about minutes. The pipe liner is then depressurized and both manifolds and the pig are removed. Both ends of S' the liner are subsequently flared, as described Sr. previously, and the fluid service is reconnected.
S« It has been found that if the service is reconnected and pressure applied to the interior of the liner from the service fluid flowing through the liner within a predetermined time, for example, within about 24 hours after completion of the liner installation, particularly after the liner has been depressurized, such pressure will ensure that the liner conforms to the walls of the existing pipe. It has also been found that over time, for example, on the order of about 3 or 4 weeks, the stresses within the liner are relieved and the liner will remain II0 ~-tr^1generally cylindrical, even when the pressurized service fluid is subsequently removed. Consequently, the foregoing lining process may be used for lines that are not normally under pressure, provided the is maintained within the liner for the predetermined time necessary to relieve the stresses in the liner tending to deform the liner to its initial deformed shape. The time required is a 9, function of the diameter, wall thickness and material of the liner and t'he degree of circularity required.
.9 For example, if an expanded but non-cylindrical configuration of the liner in the pipe is acceptable, 4 the time period during wbich the liner is held und~er 49499*pressure may be less than one week, On the other hand, such time period should be on the order of 3-4 weeks if a perfectly cylindrical liner is required.
*0 So Consequently, the use of high temperature fluids to 4 4 relieve the stresses in the liner as previously discussed is not necessary where the pressure can be 2,0 maintained in the liner for a predetermined time period after'mechanical reformation. This technique is therefore particularly useful for relining pipes 9 Wherein fluid under pressure is the typical fluid being transmitted by the pipe, While the invention has been described in j connection with what is presently considered to be the most practical and preferred embodiment, it is to be understood that the invention is not to be limtted to the disclosed embodiment, but or the contr~ary, is M L4 so intended to cover various modifications and equivalent arrangements included within the spirit and scope of the appended claims.
The claims form part of the disclosure of this specification.
1t I S 5444t e E1

Claims (27)

1. A method for producing a deformed pipe liner from an extruded tubular cross-section for insertion into a pipe line and reformation substantially to said extruded tubular cross-section, comprising the steps of: extruding plastic material at a raised temperature into an initial elongated tubular cross-section having a predetermined outside diameter and an elongated axis; collapsing the tubular cross-section at a reduced temperature above ambient temperature by depressing one side thereof generally diametrically toward an opposite side thereof and toward said axis along a plane of bilateral symmetry on opposite sides, of which side sections of the tubular cross-section bend into double-wall configurations; during collapsing, backing the opposite side of tho tubtllar cross-section along the plane of bilateral symmetry, thereby reducing the cross- sectional configuration of said tubular cross- section for insertion into the pipe line and reformation therein substantially to its -i initially extruded tubular cross-section; reducing the temperature of the collapsed cross- section to form the deformed pipe liner; and disposing a rail along the plane of bilateral *D symmetry inwardly of the distal ends of said side 4 sections to maintain the liner in the collapsed cross-section and reducing the temperature of the collapsed cross-section about the rail to ambient temperature; whereby, as a result of carrying out steps the collapsed cross-section is maintained solely by the plastic material of the liner.
2. A method as set forth in Claim 1, wherein the O/AT step of collapsing the tubular cross-section includes folding the one side progressively toward the opposite Sside, thereby progressively dimensionally reducing the bcspe.007/pipe712 91 2 i? 52 4 94 4 4 9i 9 t ii 9 9944 4 4 9' 9 i 4 4 (L ml 99 a i 4 44 49 A- 9p 9 94 I, 25' l tubular cross-section.
3. A method as set forth in Claim 1, wherein the plastic material is a thermosetting polyethylene and wherein the step of extruding is accomplished at a temperature of about 250"F to 300°F.
4. A method as set forth in Claim 1, including displacing the opposite side sections of said double-wall configurations laterally toward the plane of bilateral symmetry.
5. A method as set forth in Claim 4, wherein collapsing the tubular cross-section includes folding the one side progressively toward the opposite side, thereby progressively dimensionally reducing the tubular cross- section, and progressively displacing said opposite side sections toward one another toward the plane of bilateral symmetry.
6. A method according to Claim 4, wherein collapsing the tubular cross-section includes folding the one side and locating the fold on the side of the axis closest to the opposite side of the tubular cross-section,
7. A method for producing a deformed pipe liner from a tubular cross-section for insertion into a pipe line and reformation substantially to said tubular cross-section, comprising the steps of: collapsing the tubular cross-section at a temperature above ambient temperature by depressing one side thereof generally diametrically toward an opposite side thereof and toward said axis along a plane of bilateral symmetry on opposite sides of which, side sections of the tubular cross-section bend into double-wall configurations; during collapsing, backing the opposite side of the tubular cross-section along the plane of bilateral symmetry and displacing the oppos.ie side sections of said double-irall configurations la6trally toward the plane of bilateral symmetry, thereby reducing the cross-sectional configuration of said tubular cross-section for bcspe.007/pipe712 91 2 12 53 a 4i 4 a, a, a, 0 #4 F S* 4## a Sgl S a~ S* 4 5 i pa *6 insertion into the pipe line and reformation therein substantially to its initially tubular cross-section; reducing the temperature of the collapsed cross- section to form the deformed pipe lIner; and disposing a rail along the plane of bilateral symmetry inwardly of the distal ends of said side sections to maintain the liner in the collapsed cross-section and reducing the temperature of the collapsed cross-section about the rail to ambient temperature; whereby, as a result of steps the collapsed cross-section is maintained solely by the plastic material of the liner.
8. A method as set forth in Claim 7, wherein the step of collapsing the tubular cross-section includes folding the one side progressively toward the opposite side thereby progressively dimensionally reducing the tubular cross-section.
9. A method as set forth in Claim 7, wherein the step of collapsing the tubular cross-section is at a temperature to prevent elongation of the plastic material.
10. A method as set forth in Claim 7, wherein the step of collapsing the tubular cross-section includes folding the one side progressively toward the opposite side, thereby progressively dimensionally reducing the tubular cross-section, and progressively displacing said opposite side sections toward one another toward the plane of bilateral symmetry.
11. A method as set forth in Claim 10, where n the step of collapsing the tubular cross-section and d* ;Bacing the side sections is accomplished at a temperature to prevent elongation of the plastic material.
12. A method according to Claim 7, wherein the step of collapsing the tubular cross-section includes folding the one side and locating the fold on the side of the axis closest to the opposite side of the tubular cross-section.
13. An apparatus for producing a deformed pipe liner from an extruded tubular cross-section of plastic material bcspe.007/pipe712 91 2 12 i _.i1 54 comprising: at least one rotatable back-up roller disposed on an axis parallel to an axis of, and generally in opposition to, at least one rotatable shaping roller; the back-up roller having a curved concave spool- shaped periphery centred at a plane of bilateral symmetry and adapted to engage a back-up portion of the tubular cross-section; the shaping roller having a periphery non- complementary in shape to the periphery of said back-up roller and including a curved convex fold initiating and fold shaping peripheral surface at said plane of bilateral symmetry so that when said tubular cross-section passes generally between said back-up and shaping rollers, a 15)1 deformable portion of the tubular cross-section is Sdepressed diametrically toward the back-up portion thereof and along the plane of bilateral symmetry, so that opposite side sections of the tubular cross-section bend into double-wall configurations with a fold thereof juxtaposed to said opposite back-up portion of the tubular cross- section; such that the cross-sectional configuration of the tubular cross-section is altered and reduced; and a rail disposed generally along said plane of bilateral symmetry downstream of said back-up and shaping rollers and between said side sections.
14. An apparatus according to Claim 13 including ,means for applying heat to the pipe liner as the back-up and shaping roller deform the pipe liner to its reduced cross-sectional configuration. An apparatus according to Claim 14 wherein said heat applying means applies heat to the. liner as the liner is disposed between said side sections. An apparatus for producing a deformed pipe liner from an extruded tubular cross-section of plastic material comprising; at least one rotatable back-up roller disposed on an |2 J/ axis parallel to an axis of, and in opposition to, at least one rotatable shaping roller, I 55 4* 4,i 4* 4 '9 4 9i 44 4 4 Is 4; 430 the back-up roller having a curved concave spool- shaped periphery centred at a plane of bilateral symmetry and adapted to engage a back-up portion of the tubular cross-section, the shaping roller having a periphery non- complement nry in shape to the periphery of said back-up roller and including a pair of curved concave surfaces extending about the periphery of said shaping roller and a curved convex fold initiating and fold shaping peripheral surface at said plane of bilateral symmetry intermediate said concave surfaces so that when said tubular cross- section passes between said back-up and shaping rollers, a deformable portion of the tubular cross-section is depressed diametrically toward the back-up portion thereof and along the plane of bilateral symmetry, so that opposite side sections of the tubular cross-section bend into double wall configurations with a fold thereof juxtaposed to said opposite back-up portion of the tubular cross-section, such that the cross-sectional configuration of the tubular cross-section is altered and reduced without elongation.
17. The apparatus for producing a deformed pipe liner as set forth in Claim 16, wherein the at least one back-up roller is in opposition to two shaping rollers disposed in parallel axes parallel to the axis of the back-up roller for disposition on the side of the tubular cross-section opposite the back-up roller, the first mentioned shaping roller comprising one of said two shaping rollers.
18. The apparatus for producing a deformed pipe liner as set forth in Claim 16, wherein the at least one back-up roller has opposite flaring tapering side flanges adapted to embrace the opposite side sections of the tubular cross- section.
19. The apparatus for producing a deformed pipe liner as se. forth in Claim 16, wherein the at least one of the rotatable rollers is powered by torque means for assisting rotation thereof and advancement of the tubular cross- section therethrough. The apparatus for producing a deformed pipe liner bcspe.007/pipe712 91 2 12: -56 as set forth in Claim 16, and including means for heating the tubular cross-section of plastic material at a temperature that enables bending and prevents elongation thereof.
21. An apparatus for producing a deformed pipe liner from an extruded tubular and substantially circular cross- section of plastic material comprising: at least one rotatable back-up roller disposed on a first horizontal axis, to the axis of and in opposition at least one rotatable shaping roller disposed on a second horizontal axis substantially parallel to said first axis and vertically spaced relative thereto, the back-up roller having a concave spool-shaped periphery centred at a plane of bilateral symmetry and adapted to engage a back-up portion of the tubular cross- section, the shaping roller having a convex fold initiating and fold shaping perimeter at said plane of bilateral symmetry and adapted to depress a deformable portion of the tubular cross-section diametrically toward the back-up portion thereof and along the plane of bilateral symmetry so that opposite side sections of the tubular cross-section bend into double wall configuration with a fold thereof juxtaposed to said opposite back-up portion of the tubular cross-section, and a pair of laterally positioned rotatable shaping rollers disposed on generally vertical axis at opposite side of the plane of bilateral symmetry and each having a concave curvilinear periphery adapted to engage and further depress the double wall configurations of the side sections laterally inward toward the plane of bilateral symmetry by bending the double wall configurations of the opposite side sections, so that when said tubular cross-section passes between the back-up roller and shaping roller and then I between said pair of laterally positioned shaping rollers, S/the tubular cross-section is altered and reduceu and the opposite side sections thereof are collapsed inwardly from 0 a top dead center position thereof coincidental with the bCspe-007/p!e7l2 91 2 12 57 4 L II1 It t I #4r L444 4 4* 94 4 4 44 4 ,u5 4rr 9 plane of bilateral symmetry.
22. The apparatus for producing a deformed pipe liner as set forth in Claim 21, wherein the pair of laterally positioned shaping rollers have peripherally juxtaposed side flanges adapted to capture the finally collapsed tubular cross-section.
23. The apparatus for producing a deformed pipe liner as set forth in Claim 21, and further comprising a rail carried by said apparatus following said shaping rollers and said back-up roller and having a generally hour-glass cross-section adapted to conform to inner wall portions of the double wall configuration of the opposite side sections, said rail surface adapted to have sliding engagement with the tubular cross-section.
24. The apparatus for producing a deformed pipe liner as set forth in Claim 21, and further including a first heating means located at the shaping rollers for maintaining the tubular cross-section of plastic material at a temperature that enables bending and prevents elongation thereof, and a cooling means located at the rail and following the first heating means for reducing the temperature of the collapsed tubular cross-section to ambient for delivery of the finished deformed pipe liner.
25. The apparatus for producing a deformed pipe liner as set forth in Claim 21, and further comprising a rail carried by said apparatus following said shaping rollers and said back-up roller and adapted to conform to inner wall portions of the double wall configurations of the opposite side sections, said rail having a surface portion in sliding engagement with the tubular cross-section.
26. The apparatus for producing a deformed pipq liner as set forth in Claim 25, including a heating means located at the shaping rollers for maintaining the tubular cross- section of plastic material at a predetermined temperature and a cooling means located at the rail and following the heating means adapted to reduce the temperature of the collapsed tubular cross-section from about said predetermined temperature to ambient.
27. Apparatus as defined in Claim 26 or Claim 24, I 41 4 a bcspe.007/pipe712 91 2 12 7 58 wherein said heating means comprises a plurality of fluid nozzles.
28. A process for installing a hollow thermoplastic liner in a pipe wherein the process is characterised by the steps of: i producing a deformed pipe liner in accordance with any Sone of method claims 1 12, pulling said deformed pipe liner into said pipe such that said deformed liner extends beyond opposite ends of said pipe; reheating said deformed liner to a temperature above the crystallisation temperature of said deformed liner to F cause said liner to return to its tubular cross-sectional size and shape; and, subsequently, 1 increasing pressure within said liner to cause said Splliner to conform to interior contours of said pipe. S29. The process according to claim 28 further characterised by the steps of cleaning the interior of the pipe before the pipe liner is pulled onto said pipe, introducing a pulling line at an upstream end of the pipeline and pulling it through the pipe, attaching said pulling line at an upstream end to said liner, partially expanding the liner by mechanical means inserted into both ends of said liner introducing an expansion pig into said liner to further expand said liner against said pipe and forming radial flanges at opposite ends of said liner. Sp 30. A method for producing a liner fop a pipe substantially as hereinbefore described with reference to Figures 2 and 7 of the accompanying drawings.
31. An apparatus for producing a liner for a pipe substantially as hereinbefore described with reference to the accompanying drawings.
32. A process for installing a liner in a pipe substantially as hereinbefore described with reference to the accompanying drawings. DATED this 12 February, 1991 SMITH SHELSTON BEADLE SFellows Institute of Patent Attorneys of Australia Patent Attorneys for the Applicant: 0. V PIPE LINERS, INC. I^ i S'
AU18938/88A 1987-07-27 1988-07-11 Improved pipe liner process and apparatus Ceased AU610196B2 (en)

Applications Claiming Priority (6)

Application Number Priority Date Filing Date Title
US077883 1987-07-27
US07/077,883 US4863365A (en) 1987-07-27 1987-07-27 Method and apparatus for deforming reformable tubular pipe liners
US07114949 US4985196B1 (en) 1987-10-30 1987-10-30 Pipe liner process
US114949 1987-10-30
US188468 1988-04-29
US07188468 US4986951B1 (en) 1987-07-27 1988-04-29 Pipe liner process

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AU1893888A AU1893888A (en) 1989-01-27
AU610196B2 true AU610196B2 (en) 1991-05-16

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CH679845A5 (en) 1992-04-30
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RU2039314C1 (en) 1995-07-09
BR8803717A (en) 1989-02-14
ES2054808T3 (en) 1994-08-16
HK19695A (en) 1995-02-24
EP0301697A2 (en) 1989-02-01
CA1312716C (en) 1993-01-19
DE3889992D1 (en) 1994-07-14
EP0301697B1 (en) 1994-06-08
AU1893888A (en) 1989-01-27
EP0301697B2 (en) 1999-08-11
JPS6456531A (en) 1989-03-03
CN1016407B (en) 1992-04-29
EG18534A (en) 1993-08-30
JP2728266B2 (en) 1998-03-18
EP0301697A3 (en) 1990-10-17
CN1031812A (en) 1989-03-22
DE3889992T2 (en) 1995-01-19

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